RU2230995C2 - Method of air conditioning and plant for realization of this method - Google Patents

Abstract

FIELD: air conditioning systems for living and industrial rooms.

SUBSTANCE: proposed method includes forming twisted main air flow, spraying sprinkling liquid, separating excessive liquid from air, preheating air and supplying air to consumer. Sprinkling liquid is sprayed over circumference coaxially relative to axis of twisting of main air flow at simultaneous delivery of two air flows in tangential and vertical directions so that sprayed liquid is located between them at first time. Additional vertical flow of air is introduced into zone bounded by circumference of spraying. Conditioned air is discharged through passage located at axis of circumference of air twisting. Plant proposed for realization of this method includes housing, outlet air duct mounted coaxially relative to housing and provided with reflector with cylindrical baffle plate and separator at air intake end. Ring-shaped pipe provided with injectors and mounted in upper part of housing is used for spraying water under action of pump. Housing is provided with tangential supply branch pipe for twisting air flow and additional upper branch pipe for introducing to zone bounded by ring-shaped pipe. Excessive moisture is separated by means of taper reflector provided with cylindrical baffle plate and separator; air is preheated in outlet air duct by means of calorifer and is directed to consumer through fan.

EFFECT: enhanced efficiency due to increased surface of interaction of two media; reduced power requirements.

4 cl, 2 dwg

Description

The invention relates to methods and means for air conditioning and can be used to create the necessary air parameters both in the production process and in residential buildings and structures.

Nowadays, air conditioning systems are widely used in installations based on swirling air flows. The advantage of these installations is that when the air stream is twisted, a turbulent air flow is obtained with a higher velocity around the fluid particles and a larger surface for the interaction of the two media. These conditions make it possible to improve heat and mass transfer in the process of obtaining the necessary air parameters. However, it is not possible to fully create the indicated conditions by existing methods and installations.

So, for example, in the known method implemented in a device for humidifying gas (see AS USSR No. 1488684, class F 24 F 6/00), a swirling flow created by tangential air inlet into the device’s body by its further movement around the central vertical duct downward and its subsequent exit through this duct, it is designed to untwist and spray liquid inside a truncated cone mounted coaxially with the outlet duct.

The disadvantages of this method and device for its implementation is that the unwinding of the liquid, spraying and humidification of the air occur due to one swirling stream, which does not provide sufficient crushing of the liquid particles and does not provide a sufficient surface for the interaction of two media. In addition, due to the limited exit zone of the air, the inner surface of the cone can carry large droplets of liquid into the outlet duct.

More perfect from the standpoint of spraying liquid, the interaction of liquid and swirling air, as well as the subsequent separation of these two media is a known method implemented in an installation for air conditioning (see AS USSR No. 514994, according to class F 24 F 1/02 - prototype).

The known method, taken as a prototype, includes the following operations: tangential air inlet with swirling in a hollow vertical cylinder, spraying fluid from the swirl axis, separating the fluid from the air, counter flow of a portion of the main air flow along the swirl axis into the discharge zone, air heating and tangential conclusion to the consumer.

A well-known installation that implements the indicated method and is taken as a prototype by us contains a fan, a pump with a piping system, a cylindrical body equipped with inlet and outlet nozzles located tangentially to its circumference, a tubular element forming an annular chamber with a housing in which air heaters are installed, an atomizer liquid, installed along the axis of the tubular element in its upper part, and in the lower part of the tubular element is mounted located with a gap relative to its end face, a disk having a hole.

Thus, the installation consists of two cylindrical chambers of different diameters. Moreover, the chamber of smaller diameter, into which the source air is tangentially supplied, enters the chamber of larger diameter, from which the prepared air is tangentially discharged. In a chamber of a smaller diameter, the tangentially supplied air is sprayed with liquid using a spray gun and, saturating, it is lowered down onto the reflective disk with a hole for supplying oncoming air, which is part of the main tangential flow. Rising along the annular chamber and warming up, the air is forced out upward and tangentially discharged.

The disadvantages of this method and device for its implementation is that the swirling of the source air in the hollow cylinder (tubular element) leads to the formation of a rarefaction zone along the axis of the tubular element, the presence of which eliminates the use of the entire volume of the chamber for heat and mass transfer processes and requires a significant diameter to reduce energy consumption to swirl air. The oncoming air flow acts only in the zone of mixture exit from the reflector, and not from the moment of liquid spraying. The oncoming flow along the swirl axis does not increase the turbulence of the entire flow. These shortcomings lead to a decrease in the efficiency of heat and mass transfer and the bulkiness of the structure. In addition, the location of the air heater in a large-diameter chamber along its periphery leads to an increase in metal consumption and complexity of the design.

The objective of the present invention is to increase the efficiency of heat and mass transfer processes and reduce energy consumption during air conditioning by eliminating the discharge zone when swirling the air flow, creating conditions for turbulent flow, and also reducing the metal consumption of the structure by arranging a heater for heating the air in the exhaust duct of a smaller diameter.

To accomplish this task in the conditioning method, including the creation of a swirling main air stream, spraying the irrigation liquid, separating the excess liquid from the air, heating the air and discharging the conditioned air to the consumer, the irrigation liquid is sprayed around the circumference, coaxial to the axis of twisting of the main stream, an additional vertical stream is introduced in the area bounded by the spray circle, the output of conditioned air is produced through a channel located inside the swirling stream.

To accomplish this task in an installation that implements the proposed method, which includes a fan, a pump with a piping system, a cylindrical housing, an inlet pipe located tangentially to the housing, an outlet duct, a liquid atomizer, a reflector, an air heater, the housing is equipped with an additional upper inlet pipe, an atomizer made in the form of an annular pipe located at the top of the housing coaxially with it, with nozzles, covering the place of introduction of an additional upper nozzle into the housing, the outlet to The air duct is installed along the axis of the housing, and the conical reflector is equipped with a cylindrical visor and is fixed in the lower part of the outlet duct.

A heating air heater can be installed in the outlet duct of the installation.

A plate separator may be located under the conical reflector.

The essence of the invention lies in the fact that in the method of air conditioning, the irrigation liquid is sprayed annularly with the simultaneous supply of two air flows in the tangential and vertical directions so that the atomized liquid is initially located between them. The tangentially introduced air captures the vertical air flow from within the annular spraying together with the liquid particles. Moreover, the imposition of two flows leads to a turbulent flow of air along with the particles of the liquid and to their crushing with a simultaneous increase in the surface of interaction of two media throughout the body. Further twisting and movement of the liquid with air is carried out around the vertical outlet duct, that is, in the annular chamber, and not in the hollow cylinder. The spiral motion of the mixture with the separation of the liquid from the air is carried out due to centrifugal forces on the surface of the conical reflector, which provides an increase in the speed of blowing of the liquid particles by air. The conical reflector provides the transition of a helically falling air with atomized liquid into a rotational movement. At the same time, on the surface of the reflector, air gives the particles of the liquid the maximum centrifugal force at the minimum energy cost due to the conversion of the energy of motion.

Installation for implementing the proposed method of air conditioning is shown in figure 1 is a General diagram, figure 2 is a top view.

The air conditioning installation includes a cylindrical body 1 and an outlet pipe 2 installed along its axis with a conical reflector 3, equipped with a cylindrical visor 4 and a separator 5. In the duct 2 there is a heating air heater 6, a throttle valve 7 and a fan 8. connected to it housing 1 fit: inlet tangential pipe 9 with a throttle valve 10, an additional upper supply pipe 11 with a throttle valve 12. In the upper part of the housing 1 is installed associated with the pump m 13 ring irrigation pipe 14 with nozzles, which is connected through a system of pipes with pipe fittings 15.

The outlet duct 2 and the annular pipe 14 are installed coaxially with the cylindrical body 1. The upper supply pipe 9 is installed asymmetrically to the axis of the housing 1 within the area bounded by the circumference of the annular pipe 14. The installation tray where the liquid is located may be provided with heating elements 16 for heating the liquid.

Installation works as follows. When starting the fan 8, the vacuum from the suction pipe is transmitted through the throttle 7, air heater 6, the vertical duct 2 and the separator 5 into the housing 1. Under this action, there is both a tangential air supply through the pipe 9 and an additional vertical air flow through the upper pipe 11 causing flow turbulence. In the upper part of the housing 1, atomized liquid is pumped into these flows, which is pumped out of the installation sump by means of a pump 13 through an annular irrigation pipe 14 with nozzles. In this case, the temperature of the sprayed liquid can be maintained either from the operation of the heating elements 16, or from the supply of cold and hot water using pipe fittings 15. The operation of the heating elements 16, the supply of cold and hot water, as well as turning on and off the air heater 6, which provides the second air heating, are carried out automatically by means of temperature regulators.

The liquid sprayed by the nozzles in the air stream saturates it to 100% relative humidity and heats it to the required temperature. Then the mixture of liquid and air helically around the vertical duct 2 is lowered to the surface of the reflector 3, where the translational energy of the mixture is converted into rotational. 3a, due to centrifugal forces, liquid droplets are discarded to the periphery of the housing 1, and with further movement of the mixture between the surface of the housing 1 and the guide visor 4, the mixture is divided into liquid and air. The air deviates to the guide visor 4 and goes into the separator 5, and liquid droplets fall down into the pallet along the wall of the housing 1. Part of the droplets carried away with air are finally separated in the separator 5, and the air moves along the vertical duct 2 into the air heater 6, where it is heated to obtain the necessary air parameters for temperature and relative humidity, then with a fan 8 is sent to the consumer. The total flow rate of the prepared air is regulated by the throttle valve 7, and the ratio of the tangential and vertical air flows is set by the throttle valves 10 and 12.

Thus, the presence of the upper additional 11 and tangential 9 nozzles, providing air inlet into the cylindrical housing 1, increases the turbulence of the air flow and improves the interaction with the sprayed liquid. The presence of a vertical inlet air outlet 2 with a conical reflector 3 provides a more efficient use of the internal space of the housing 1 without a vacuum zone, and the conical reflector 3 creates an unwinding of fluid particles with a message to them of centrifugal force with minimal energy expended and further efficient separation of air from the liquid using the guide visor 4 All these conditions create effective heat and mass transfer upon receipt of the necessary air parameters. The location of the heater 6 in the outlet duct with a small diameter reduces the metal consumption and simplifies the design of the air conditioner.

Using the installation that implements the proposed method of air conditioning in the line for baking bakery products for air preparation in the proofer showed that at an ambient temperature of 24-28 ° C, air capacity up to 7 thousand m ³ / h with output parameters for relative humidity 60-70%, at a temperature of 36-40 ° C, the energy consumption was 10-12 kWh, which is 1.5-2.0 times lower compared to existing air conditioners of the same class.

Claims (4)

1. The method of air conditioning, including the creation of a swirling main flow of air, spraying the irrigation fluid, separating the excess fluid from the air, heating the air and the outlet of the conditioned air to the consumer, characterized in that an additional vertical flow is introduced into the main flow, the irrigation fluid is sprayed around coaxial axis of twisting of the main stream, and an additional vertical stream is introduced into the main stream into the zone with a radius of twist less than the radius of the spray zone o growing fluid, the output of conditioned air is produced through the outlet duct located along the axis of the swirling flow. 2. Installation for air conditioning, including a fan, a pump with a piping system, a cylindrical housing, an inlet pipe located tangentially to the housing, an exhaust duct, a liquid atomizer, a reflector, a heater, characterized in that the housing is equipped with an additional upper supply pipe, the sprayer is made in the form of an annular pipe with nozzles located in the upper part of the body, coaxially with it, covering the place of introduction of an additional upper nozzle into the body, the outlet duct ene of the body axis, a conical deflector is mounted in the lower portion of the outlet duct and is provided with a cylindrical shield. 3. Installation according to claim 2, characterized in that the heating air heater is installed in the outlet duct. 4. Installation according to claim 2, characterized in that a plate separator is located under the conical reflector.

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